Coordinatore | FONDAZIONE ISTITUTO ITALIANO DI TECNOLOGIA
Organization address
address: VIA MOREGO 30 contact info |
Nazionalità Coordinatore | Italy [IT] |
Totale costo | 185˙763 € |
EC contributo | 185˙763 € |
Programma | FP7-PEOPLE
Specific programme "People" implementing the Seventh Framework Programme of the European Community for research, technological development and demonstration activities (2007 to 2013) |
Code Call | FP7-PEOPLE-2011-IEF |
Funding Scheme | MC-IEF |
Anno di inizio | 2012 |
Periodo (anno-mese-giorno) | 2012-07-22 - 2014-07-21 |
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FONDAZIONE ISTITUTO ITALIANO DI TECNOLOGIA
Organization address
address: VIA MOREGO 30 contact info |
IT (GENOVA) | coordinator | 185˙763.60 |
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'The objective of the present project is a development of approaches for facile colloidal synthesis of Cu-containing semiconductor nanocrystals, characterized by low production cost, high stability, high photoluminescence efficiency and low toxicity. The materials that will be synthesized will undergo comprehensive physico-chemical characterization including a deep assessment of their toxicity and will be evaluated as light absorbing components for fabrication of excitonic solar cells.
Copper chalcogenides represented by binary, ternary and quaternary compounds, like CuS(Se,Te), CuIn(Ga)S(Se,Te), CuZnSnS(Se,Te) are one of the most attractive series of low-toxic semiconductor materials, which are truly alternative to the widely studied cadmium, mercury and lead chalcogenides. This new generation of semiconductor nanocrystals is now being in the focus of a great scientific interest. These nanocrystals are characterized by tunable visible and near infrared emission and absorption properties and high extinction coefficients and therefore hold great promise in bio applications, in light emitting diodes fabrication, photovoltaics and optoelectronics.
This project will provide new knowledge into the mechanisms governing the reactions involving the various precursors during the stages of nanoparticle nucleation. This new knowledge will then allow for a proper control of nanoparticles crystal structure, composition, size, shape, and consequently of their optoelectronic and photovoltaic properties. The synthesized and fully characterized copper chalcogenide nanoparticles will be used for fabrication of solar cells. Combination and adaptation of state-of-the-art approaches as well as creation of novel synthetic methods will result in innovative investigation covering wide range of tasks from the synthesis of novel materials through their comprehensive characterization and ending with their application in photovoltaics.'
Novel biocompatible semiconductor compounds produced with simple, low-cost and scalable processes promise major impact on fields from energy to biomedicine.
Colloidal materials take advantage of inexpensive synthesis and subsequent processing routes. Copper is inexpensive, abundant and has relatively low toxicity compared to heavy metals commonly used in many semiconductor materials. Taken together, colloidal copper chalcogenides are a winning combination.
The EU-funded project 'Low-toxicity copper chalcogenide semiconductor nanocrystals' (LOTOCON) focused on scalable and controllable synthesis of binary copper chalcogenides followed by partial cation exchange. The partial replacement of copper ions by others was planned to enhance tuneability of composition and morphology. Scientists chose the simplest copper chalcogenides as the starting point, nanoparticles consisting of copper sulphide (Cu2S), selenium and tellurium.
Team members developed a novel synthetic route to their controlled production at moderate temperatures, avoiding the use of harmful and expensive phosphines. A variety of shapes were produced from small spherical particles to large and thin 2D sheets. The materials were successfully used as cathodes for fabrication and testing of lithium-ion batteries. Importantly, the method was easily scaled, offering great potential for industrial manufacture.
Subsequent work on partial cation exchange led to easy production of alloyed nanoplates with a tuneable band gap. The strategy was also applied to the much larger copper selenide nanosheets produced within the project. The materials were subsequently processed into thin films and implemented in solar cell devices.
The cation exchange route is broadly applicable to a variety of cations and copper chalcogenide nanoparticles. This provides an industrially important route to a number of materials that would otherwise be difficult to produce.
Building on these results, the team developed a one-pot synthesis method using Cu2S nanocrystals and partial cation exchange of Cu with indium and zinc, leading to enhanced photoluminescence efficiency and tuneable light emission. Cytotoxicity tests confirmed biocompatibility, opening the door to application as fluorescent biomarkers. Along the way, the team shed important light on the mechanisms of cation exchange, a widely used yet poorly understood process, which will aid in knowledge-based design and synthesis.
The work has been widely published in prestigious peer-reviewed scientific journals. LOTOCON technology is expected to have widespread impact on industrially relevant fields, including solar cell technology, catalysis and biomedicine.